SE436455B - STRING INSTRUMENT RESONANCE BOTTLE - Google Patents

Description

soo29s1-1 ensures such a small attenuation on the oscillations transmitted on it and thereby ensures an increase in the sound reproduction in the entire interesting frequency range, whereby the degree of attenuation achieved by the structure can be affected.

This object is achieved by means of the resonant bottom mentioned in the introduction, which is characterized in that a metal plate, preferably a steel plate, in the form of a strength-increasing plate with a modulus of elasticity and an internal damping, corresponding to a steel of quality St 3Ä, on both sides above the entire surface is connected to one or more covering layers of wood running parallel to the metal plate or a material with damping properties, which essentially corresponds to the damping properties of wood.

Admittedly, resonant bases have been proposed, which consist of a sheet-shaped foamed plastic material with a small thickness of about 0.05-0.3 mm, which is coated on both sides with layers of material with a higher modulus of elasticity, such as wood or fiberglass-reinforced plastic, but with such resonant bottoms the high attenuation caused by the thin layer of foamed plastic does not achieve an increase in the sound reproduction over the entire frequency range of interest. The attenuation caused by the said disc-shaped part of foamed plastic of small thickness cannot be reduced hellex * even by the applied reinforcement layers of material of greater thickness, such as e.g. wood or fiberglass-reinforced plastic.

In contrast, in the case of the application object, the metal plate covered on both sides is the vibration-absorbing part, which has a very small attenuation and which is only provided with the attenuating cover layers to such an extent that a sound reproduction without sharp and pronounced resonances occurs at single frequencies. It is thus possible to achieve an optimal attenuation over the entire frequency range affecting the sound effect and also to influence the degree of attenuation by choosing materials as well as the structure of the cover layers depending on the metal plate used.

It is particularly expedient to design the cover layers of a plurality of wood layers or wooden boards, the fiber directions for adjacent wooden boards running at approximately right angles to each other. This avoids unfavorable voltage conditions in the resonant bottom.

The wood layers used do not have to have the same quality as is required for the production of resonant bases of solid spruce wood. On the contrary, wood qualities for the cover layers can be used, which are available to a sufficiently high degree also in the future. Instead of the mentioned wooden boards, according to another embodiment of the invention, the cover layers arranged on the metal board can also consist of a plastic coating, and in particular of plastic boards or plastic laminates in which adjacent layers consist of fibers running at approximately right angles to each other. materials and laminates respectively, varying damping properties of the cover layers are obtained.

To achieve a further improvement of the sound reproduction of the resonant bottom, it is advisable to reduce the bending stiffness of the metal plate in the edge area relative to the middle part of the metal plate by punching or punching in the edge zones or by arranging folds along the edges. This improves the oscillation capacity of the resonant bottom and thereby creates favorable conditions for the oscillation transmission.

In order to achieve the above-mentioned, varying bending stiffness in the edge region and intermediate region of the resonant bottom, in addition to the above-mentioned measures or independently thereof, the metal plate in the middle part can be formed more rigid than in the edge zones by metal strips, preferably steel strips. Such steel strips are preferably used when a very thin metal plate is used, the flexural stiffness of the central area of which is increased in the manner described at no greater cost.

The thickness of the hot plate is preferably substantially less than the thickness of the cover layers, the ratio between the thickness of the metal plate and the thickness of the cover layers preferably being about 1: 3-1: 6 and the metal plate having a thickness of about 0.5-1.5 mm. Said dimensions have proved to be particularly favorable for metal plates in the form of a strength sheet consisting of steel with the quality St 50.

The drawings show exemplary embodiments of the invention in schematic form, in which Fig. 1 shows a schematic longitudinal section through the rear part of a piano, fig. Fig. 2 shows a perspective and partially sectioned embodiment of the resonant bottom according to the invention, Fig. 3 shows another design of the resonant bottom in the same view as in Fig. 2, Fig. 4 shows a plan view of a further embodiment of the resonant bottom, Fig. 5 shows a section along the section line VV in Fig. H, Fig. 6 is a plan view similar to that in __. f,., _. V ... ø-.h .- .-. ».-.- 8002931-'7 fig. H of another embodiment, fig. 7 shows a section along the line VII-VII in fig. 6, and Fig. 8 is a partial cross-section through a resonant bottom with associated stables.

In Fig. 1, which shows the principle of a piano sound body, the cast iron frame is denoted by 1, which is known to be annularly closed and whose enclosed opening is spanned by the strings 2. The strings are attached at one end to tuning screws 3, which by openings in the frame 1 extend into a tuning stick H.

The strings 2 rest against a stable 5, which is connected to the resonant bottom 6, which is supported by a frame 7.

The abutment on the strings 2 takes place by means of a hammer 8, which is maneuvered over a mechanism not shown in more detail in the drawings.

The resonant bottom 6 constitutes a disc-shaped element with a relatively large surface area, which is conventionally made of selected, solid boards of spruce wood with an average thickness of 7-11 mm, with vertically standing annual rings.

In the new embodiment of the resonant bottom, as shown in Figs. 2-8, this consists of a metal plate 9, preferably a sheet of steel plate in the form of a strength-increasing sheet with a minimum quality of St 3%, which on both sides over the entire surface is connected to one or more cover layers of wood or a material with damping properties, which essentially correspond to the damping properties of wood. In the embodiment shown in Fig. 2, the metal plate 9 is connected on the facing sides to a cover layer 10 and 11, respectively, consisting of wood, the masonry direction of which is indicated by arrows 12 and 13. Instead of said cover layers 10 and 11 of wood These may consist of a plastic, for example in the form of a plastic board, the damping properties of which substantially correspond to the damping properties of wood. This involves plastic materials such as polyester or epoxy resin, which are reinforced by storing fibers, such as glass or mineral fibers. The reinforcement must be such that the fiber direction corresponds to the arrows 12 and 13 in Fig. 1. The thickness of the cover layers 10 and 11 then depends on the damping properties of the material used as well as on which material is chosen for the metal plate 9 for producing the resonant bottom. . On the one hand, excessively sharp resonances must be prevented from occurring, especially for high frequencies, and transmitted through the sound reproduction to the air, and on the other hand, the attenuation must be kept within such limits that indistinct tones do not occur.

In the embodiment of the resonant bottom according to Fig. 3, the metal plate 9 is covered on both sides by two cover layers 14 and 15, whereby also these layers can consist of wood or preferably reinforced plastic. The fiber direction on adjacent cover layers 14 and 15 is again indicated by arrows 16 and 17, respectively. The figure shows that the fiber direction for adjacent layers extends approximately at right angles to each other. The arrangement of two or possibly also more cover layers on each side of the metal plate 9 is undertaken, when a higher damping is desired or when required by the properties of the metal plate 9. In this case, you can combine wood and plastic layers as a cover layer.

Both in the embodiment according to fig. 2 as the one according to Fig. 3, cover layers of plastic laminate can be used, where the direction of the fibers varies from layer to layer.

In the described embodiments of the resonant bottom with the metal plate arranged between the cover layers, the metal plate forms the actual sound carrier and the vibration-absorbing part, respectively, while the cover layers take over the function of the damping layers.

Since the metal plate, especially when it is a steel plate in the form of a solid strength-increasing sheet with a minimum quality of St SU, has a very low attenuation, practically all the oscillations of the strings, and especially also the higher frequencies, are transmitted to the air while increasing the sound reproduction. .

In this case, sharp resonances can occur, which, however, can be reduced to the desired degree by the arranged damping layers.

Due to the composite structure of the resonant bottom with the intermediate layer in the form of the metal plate, an increased bending stiffness can result, which on the one hand is desirable, since it is not necessary to provide reinforcement strips, but on the other hand the oscillation properties can be adversely affected. To remedy this, according to Figs. 4 and 5, the resonant bottom inside their fastening edges, which are held in a frame, can be provided with folds 16 arranged along the edges, by reducing the bending stiffness of the edge zones. Similarly, the flexural stiffness according to the embodiments shown in Figs. 6 and 7 can be reduced by punching or punching in the edge area. Fig. 6 shows sectional punches 17, which are arranged at a distance from the edges of the metal plate 9. Instead of such punches or punches in slit form, other punches can also be arranged, for example elongate holes or the like. In Figs. 6 and 7 it is further shown that the middle area of the resonant bottom can be reinforced or stiffened by additional metal strips 18 and 19, respectively. Such band reinforcements can be used when a very thin metal plate 9 is used, which together with the cover layers does not ensure a sufficient bending stiffness for the resonant bottom.

In the exemplary embodiment according to Figs. 8 and 7, the metal strips 18 and 19 are so arranged on the mefall plate s provided with edge slots 17 that they are partially embedded in the cover layers 20 and 21 immediately adjacent to the metal plate, which may consist of wood or plastic on the described manner. For the outer cover layers 22 and 23, the fiber direction is again indicated by the arrows 2U, which runs perpendicular to the fiber direction of the cover layers 20 and 21. 1 To transmit the oscillations from the strings 2 immediately to the oscillation bearing part of the new resonant bottom, i.e. to the metal plate 9, according to Fig. 8 the stable 25 supporting the strands 2 can be fastened immediately to the metal plate 9, a gluing or gluing 26 and in addition a fastening screw 27 being provided for the fastening. I fig. 8 it is assumed that it is a resonant bottom with the embodiment shown in Fig. 2, i.e. that the metal plate 9 is arranged between the cover layers 10 and 11. An opening for arranging the stable is arranged in the cover layer 11, just as an opening for the fastening screw 27 is arranged in the cover layer 10.

In the described new design not only a very large ratio between modulus of elasticity and thickness is achieved, but an oscillation absorbing part is used, which exhibits a very small damping, which can be influenced by the cover layers to produce a damping increase, while in all previously known designs of resonant bottoms the oscillation-absorbing part has a relatively high damping, which cannot be reduced by cover layers but can only be increased. Since the attenuation determines the spectrum of the oscillations that can be transmitted for the sound reproduction, it is quite clear that with the new resonant bottom significantly more favorable transmission conditions can be achieved than has been possible with the hitherto known embodiments.

Claims (8)

8020-2931 '-7 _ Patent claim The resonant bottom for string instruments, in particular piano or grand piano, characterized in that a metal plate (9), preferably a steel plate, in the form of a strength-increasing plate with a modulus of elasticity and an internal damping corresponding to a steel of quality St 34, on both sides over the entire surface are connected to one or more, covering the metal plate (10, 11; 14, 15; 20-23) running parallel to the metal plate or a material with damping properties, which substantially corresponds to the damping properties of wood. The resonant bottom according to claim 1, characterized in that when designing the cover layers of several wooden layers (lä, 15 'and 20-23), respectively, wooden plates are arranged, and that the fiber directions (17 and 24, respectively) for adjacent wooden plates run in substantially straight angle relative to each other. The resonant bottom according to claim 1, characterized in that the cover layers (12, 13; 14, 15) arranged on the metal plate (9) consist of a plastic coating, in particular of plastic plates or plastic laminates, with adjacent layers substantially at right angles to each other arranged fibers. H. The resonant bottom according to any one of the preceding claims, characterized in that the pliability of the metal plate (9) is reduced in the edge area relative to the middle part of the metal plate by punching or punching (17) in the edge zones or by arranging seams (16) along the edges. Resonance base according to one of the preceding claims, characterized in that the metal plate (9) in the middle part is formed more flexurally rigid than in the edge zones by metal strips (18, 19) inserted in the cover layers (20, 21), preferably adjustable straps. The resonant bottom according to any one of the preceding claims, characterized in that the thickness of the metal plate (9) is substantially less than the thickness of the cover layers (10, 11 and 1M, 15, respectively). 7. The resonant bottom according to any one of the preceding claims, characterized in that the thickness of the metal plate (9) relates to the thickness of the cover layers (10, 11 and 1H, 15, respectively) of about 1: 3-1: 6. and that the metal plate has a thickness of about 0.5-1.5 mm. 8. The resonant bottom according to any one of the preceding claims, characterized in that the stalls' (25) pass through holes in the cover layer or cover layer (11 and 11+, 15, respectively) and abut immediately against the metal plate as well as are connected to the metal plate. '' _..., .....- ._ -._ ~ .- ---.- »v» ~ v ---- - ~ --- ~ -vv- »fi-. Wu -.em- fi __. az. -> .-. «-